Remote diagnostic system

ABSTRACT

In the present invention, constructed is a highly reliable system that does not allow unforeseen conditions to occur in the remote diagnosis of a clamp device. All combinations of status of a state detection switch mounted on a clamp device are anticipated in advance by a recursive method, and the states are defined with no omissions. A control unit  9  includes: a main body memory  9   c  that stores the ON/OFF state of a state switch together with the status of an injection molding machine main body, the clamp status and time information; and a main body communication unit  9   d  which is capable of short-range wireless communication. A message diagnosing a failure is stored in a smartphone  12  for all combinations of the ON/OFF state of the state detection switch for each of the following cases: whether in mold replacement mode or not; and whether a clamp device is in a clamped state or an unclamped state, or in a state other than the forgoing. The history of the ON/OFF state of the state detection switch with respect to the status of the main body and the clamp status is read from the main body memory  9   c  by wireless communication, and a corresponding message is displayed.

RELATED APPLICATIONS

The subject patent application is a divisional of U.S. patent application Ser. No. 16/976,594 filed on Aug. 28, 2020 which is a national stage application of International Application No. PCT/JP2019/016924 filed on Apr. 22, 2019 claiming priority from Japanese Patent Application No. 2018-086352 filed on Apr. 27, 2018 and Japanese Patent Application No. 2018-203600 filed on Oct. 30, 2018. The entire contents of all aforementioned patent applications are incorporated herein by reference.

FIELD OF THE INVENTION

The present invention relates to a remote diagnostic system for grasping a mold replacing state in a clamp device without omission in a mold handling device.

A remote monitoring system capable of remotely monitoring a mold handling device such as an injection molding machine, a press machine, a die casting device, etc., is described for example in patent literatures 1, 2.

The patent literature 1 describes that in a display device of a management system for managing a plurality of injection molding machines, at least one kind of screen of a plurality of types of screens displayed in order to express the management status of each injection molding machine is taken into a communication terminal device through a communication network and displayed on an attached display device to monitor the operation status of each injection molding machine. One of the plurality of types of screens is an operation status screen for collectively displaying the operation status of each injection molding machine on at least one screen in real time on all the machines in a screen division format. The communication terminal device can display the operation status screen, and can display a screen showing details of the operation status of only the corresponding machine by clicking on a specific place of each machine that is divided and displayed.

In patent literature 2, injection molding machines in a production plant are respectively provided with control devices for converting operation status data such as numerical data of these injection molding machines into image data, when an operation request is made from a personal computer of an office existing in a remote place to the injection molding machines, the control devices convert the operation status data into image data and transmit the image data to the personal computer. Security safety can be improved by transmitting the data after converting into image data which cannot be easily rewritten.

On the other hand, in patent literature 3, a system that connects a detection terminal for detecting gradient brain wave of head of a driver and an on-vehicle smartphone by Bluetooth® communication to notify from the smartphone to a remote monitoring terminal is known. This technique uses a Bluetooth function of the smartphone and a communication function with remote telephones to acquire information from the detection terminal stored in the smartphone on the monitoring terminal side.

PRIOR ART Patent Literature

Patent literature 1: Japanese Patent Laid Open Publication No. 2003-1688

Patent literature 2: Japanese Patent Laid Open Publication No. 2006-110765

Patent literature 3: Japanese Patent Laid Open Publication No. 2005-79612

DISCLOSURE OF THE INVENTION Problems to be Solved by the Invention

In a mold handling device, a user who uses the mold handling device can arbitrarily select a mold clamp system for fixing a mold. Since there are many different types of clamp devices required by users, maker sides for manufacturing main bodies of mold handling devices cannot support product lineup in which the mold clamp system that meets the user's request is set as a set product in advance. Also, even after the mold handling device is installed in the factory, mechanism of the clamp device is frequently changed. Accordingly, the maker's works are divided into makers for manufacturing the main bodies of the mold handling devices and makers for manufacturing the mold clamp systems. It is often up to the production site to determine what type of clamp device to use.

In the techniques disclosed in patent literatures 1, 2, production plants are established in remote places such as overseas, and a plurality of machine tools and the like provided in the production plants are managed by each head office through communication lines. In this case, although the head office can manage the main body of the injection molding machine, it is difficult to grasp the diversity of local mold clamp systems at the head office.

Also, in the technique disclosed in patent literature 3, a smartphone is mounted on the vehicle, and the Bluetooth communication can be performed in a state in which the Bluetooth is close to the driver's detection terminal and the pairing of both is maintained. If a person's head is tilted to generate θ wave, the person is determined to be a doze. Based on this phenomenon, the detection terminal side makes a priori diagnosis that the target driver is dozing if the driver's head tilts and the θ wave is generated. In this case, if any other phenomena occur, it will be unexpected and the detection terminal side cannot cope with them. In the mold clamp system, unexpected things can happen because the types of clamping mechanisms mounted on the injection molding machines vary depending on the users.

The present invention has been made to solve such a problem, the object of the present invention is to construct a highly reliable system which does not cause unexpected conditions for the mold handling device installed in the production site, by previously assuming all combinations for the clamping mechanism which is installed at the user's option and may be changed thereafter in a recursive manner and then by fully defining states.

Means to Solve the Problem

The remote diagnostic system of the present invention refers to a remote diagnostic system of a mold handling device provided to a platen with a clamp for mounting at least two kinds of state detection switches among a state detection switch for detecting an advance position that detects whether approaching to the mold, a state detection switch for detecting a retreat position that detects whether separating from the mold to a limit position, a state detection switch for detecting that an output member of the clamp device has locked the mold, a state detection switch that detects whether or not the output member has released the mold, a state detection switch that detects whether or not a hydraulic pressure for locking a clamp rod exceeds a threshold value, and a state detection switch that detects whether or not the hydraulic pressure for releasing the clamp rod exceeds a threshold value. Here, the remote diagnostic system of the present invention includes a control unit and a smartphone, and further, the control unit has a main body side memory and a main body side communication unit, and the smartphone has a terminal side memory, a terminal side communication unit and a display unit. The main body side memory stores an ON/OFF state of the state detection switch mounted on the clamp device together with information as to whether or not the mold handling device main body is in a mold replacement mode (a main body status), information as to whether the clamp device is in a clamped state or an unclamped state or other states (a clamp status), and time information. The main body side communication unit is capable of short range wireless communication or wired communication. The terminal side memory stores a message for diagnosing a failure for all the combinations in the ON/OFF states of the state detection switch mounted on the clamp device to determine whether or not the mold handling device main body is in a mold replacement mode, whether the clamp device is in the clamped state or the unclamped state, and other states. The terminal side communication unit reads out a history of ON/OFF states of the state switch for the main body status and the clamp status from the main body side memory by the wireless communication or the wired communication. The display unit acquires and displays a message corresponding to the read history from the terminal side memory.

Effects of Invention

According to the present invention, all combinations are previously assumed for all combinations of the outputs of the state detection switch, the state of the mold handling device main body, and the clamp status in the recursive method, and diagnostic states of the clamp device are fully defined as the contents of the message for the combinations of them, and therefore, a work manager can refer to the contents of the message which can construct a highly reliable system by eliminating unexpected conditions, thereby being capable of accelerating on-site response.

BRIEF DESCRIPTION OF THE DRAWINGS

FIGS. 1A and 1B show an object to which a remote diagnostic system is applied. FIG. 1A shows a production site where an injection molding machine is installed, and FIG. 1B shows the injection molding machine.

FIG. 2 is a perspective view of a T-slot automatic slide type clamp device having a mechanical lock mechanism.

FIGS. 3A, 3B, 3C and 3D each of which explaining a clamp device, and each of FIGS. 3A, 3B shows a way in which a piston of a pneumatic cylinder causes a housing to move back and forth, and each of FIGS. 3C, 3D shows a cross section of the housing.

FIG. 4 is a figure showing a connection between the clamp device and the control unit.

FIG. 5 is a figure showing a configuration of a remote diagnostic system.

FIGS. 6A, 6B, 6C and 6D each illustrating an operation of the remote diagnostic program downloaded to a smartphone.

FIGS. 7A, 7B, 7C, 7D and 7E each showing an example in which a magnet clamp is mounted as a mechanism of the clamp device. FIGS. 7A, 7B are front views of magnet clamps on a movable platen side and a fixed platen side, respectively. FIG. 7C is an electric circuit, FIG. 7D is a power source for driving a magnetizing coil, and FIG. 7E is a diagram showing a display of the smartphone.

FIG. 8 is a figure showing a processing program for detecting whether a mold is locked.

FIG. 9 is a figure showing a processing program for detecting whether a mold is released.

PREFERRED EMBODIMENT OF THE INVENTION

FIG. 1A shows a typical production site F in which an injection molding machine is installed as an example of a mold handling device and an injection molding machine 1. In FIG. 1A, a plurality of injection molding machines 1 are installed in a row in a plant. A movable crane 2 is installed on a ceiling so as to extend over the injection molding machine 1, and transports a mold towards the injection molding machine 1. A belt conveyor 3 for conveying a material is provided on the right side in the figure.

The injection molding machine 1 in FIG. 1B includes left and right platens 4 a, 4 b, to which molds M1, M2 are respectively attached, and a guide rod 5, which guides and supports the left side platen 4 a so that it moves forward and backward in the left and right direction. Hereinafter, the moving side may be referred to as a movable platen 4 a and the fixed side may be referred to as a fixed platen 4 b in embodiments. The platens 4 a, 4 b are mounted with clamp devices 6 a, 6 b that clamp the molds M1, M2, respectively. A controller 7 with a liquid crystal display screen is what the injection molding machine 1 originally possess. A control unit 9 is an option provided by manufacturers of mold clamp systems, which controls the clamp devices 6 a, 6 b and stores signals detected by a number of state detection switches provided to the clamp devices 6 a, 6 b and then determines normal/abnormal. The control unit 9 exchanges the signals with the controller 7, and for example, receives information of “mold replacement mode” indicating that the operation mode of the injection molding machine 1 is selected in a state in which the mold replacement is performed from the controller 7. In addition, the control unit 9 sends the controller 7 information of “mold replacement-ON” indicating that the clamp system is replacing the mold and information indicating abnormality of the clamp device, and the like.

Reference numeral 8 denotes a nozzle that injects resin, and reference numeral 10 denotes an ejector rod that extrudes an injection-molded product from the mold M1. Further, reference numeral 11 is a mold auxiliary metal fitting that fixes a wire for suspending the molds M1, M2.

There are various kinds of mechanisms of the clamp devices 6 a, 6 b, and there are types including a T-slot manual type, a T-slot automatic slide type, an in-block manual slide type, an in-block automatic slide type, a block fixing type, and a type with mechanical lock mechanism. These can be further classified into hydraulic type and pneumatic type. Moreover, there are also magnet clamps that hold the molds M1, M2 by using magnetic force.

Among these, the T-slot manual type and the T-slot automatic slide type slid in T-slots that are provided in the platens 4 a, 4 b to come close to the molds M1, M2, and differ in whether the power sliding in T-slots is manual or pneumatic pressure. There are some clamp devices whose base parts are fitted to mounting screw holes of the platens by bolts in the in-block manual slide type, the in-block automatic slide type and the block fixing type. They also differ in whether the power sliding on each base part is manual or pneumatic pressure. The block fixing type is to be fixed to the mounting screw holes of the platens not to move. The mechanical lock mechanism is to mechanically exert a sufficient holding force even if the lock hydraulic pressure is lost due to breakage of pipes or the like.

Work managers H are arranged for a plurality of injection molding machines 1. The work managers H can communicate with the control unit 9 provided in each injection molding machine 1 by possessed smartphones 12 (terminal devices such as a cellular phone, a radio portable terminal and the like). In all of the injection molding machines 1, there is a possibility that the same type of clamp devices are mounted or different type of clamp devices depending on the introduction year or the use are mounted. A remote diagnostic program 25 (FIG. 5 ) is installed in each smartphone 12, and a unique diagnostic result can be found even if any type of clamp devices are installed. This will be described later.

An example in which a T-slot automatic slide type clamp device 100 having a mechanical lock mechanism shown in FIG. 2 is mounted as the clamp devices 6 a, 6 b will be explained.

In the figure, the clamp device 100 has a T-leg 101 which slides along the T-slot of the platen 4 a (or 4 b) on the bottom surface of a housing 102. A clamp rod 103 moves back and forth obliquely downward from a guide hole 104 of the housing 102 to press and fix the mold M1 (or M2) disposed on the platen 4 a (or 4 b). A pneumatic cylinder 106 is provided on the side of the housing 102 to be fixed on the platen 4 a (or 4 b) through a base 105.

A forward limit switch (forward limit LS) 107 mounted on the housing 102 is a state detection switch for detecting an advance position that detects whether the housing is close to a mold, and a proximity switch is used as the forward limit switch. The forward limit switch 107 is turned in an ON state when the housing 102 reaches a lock position for clamping the mold M1 (or M2), and in an OFF state when the housing 102 is separated. An automatic switch is used as a rearward limit switch (rearward limit LS) 108 mounted on the rear end of the pneumatic cylinder 106. The rearward limit switch 108 is to detect whether the housing is separated from the mold to the limit position, and detects movement of an output member (including a piston and a piston rod) 109 in the pneumatic cylinder. When the housing 102 reaches the limit position separated from the mold M1 (or M2), the rearward switch is turned in an ON state, and when the housing 102 approaches from the limit position to the mold, the rearward switch is turned in an OFF state.

FIG. 3 is a figure further illustrating the clamp device 100. FIGS. 3A, 3B show a status that the output member 109 of the pneumatic cylinder 106 causes the housing 102 to move back and forth along the T-slot 41. FIGS. 3C, 3D are cross-sectional views of the housing 102. FIG. 3C shows a status that the mold M1 (or M2) is locked while clamping, and FIG. 3D shows a status that it is released while unclamping.

In FIGS. 3C, 3D, the guide hole 104 is formed to be inclined in the lower left direction in each figure. While clamping, the left end (left lead end portion) of the clamp rod 103 presses and locks the mold M1 (or M2). The clamp rod 103 is provided with a clamping member 103 a provided on a part close to the left end (a part close to the left lead end portion) in the axial direction thereof, a flange 103 b and an inner piston 103 c provided on a part close to a right end (a part close to a base end), and a tapered pressure receiving surface 103 d provided on the right side of the figure of the inner piston 103 c. The pressure receiving surface 103 d is formed so that it approaches the axis center C as it moves toward the right end (base end direction).

The guide hole 104 is provided with a small-diameter hole 104 a and a large-diameter hole 104 b that are formed in this order from the left side of the figure. In the large-diameter hole 104 b, an outer piston 110 is externally inserted to the outer peripheral surface of the inner piston 103 c. Further, on the right side of the figure of the outer piston 110, a collet 111 having an inner peripheral surface along the tapered shape of the pressure receiving surface 103 d is externally inserted on the inner piston 103 c. The collet 111 is composed of four divided members arranged at substantially equal intervals in the circumferential direction. The collet 111 is divided so that when the collet 111 moves to the left along the tapered surface of the pressure receiving surface 103 d, the collet 111 can expand radially outward with respect to the axis center C. The collet 111 and the outer piston 110 have hook parts 112 a, 112 b so that the collet 111 and the outer piston 110 can move together in the direction of the axis center C of the guide hole 104. The mechanical lock mechanism of the clamp device 100 means a wedge engagement due to the collet 111, but this will be referred when explaining the operation.

An operating member 115 that operates a lock switch (a lock limit switch, hereinafter referred to as a lock LS) 113 and a release switch (a release limit switch, hereinafter referred to as a release LS) 114 is mounted on the rear side (right side in the figure) of the clamp rod 103. The lock LS 113 is a state detection switch that is turned in an ON state while clamping and that is turned in an OFF state while unclamping. The release LS 114 is a state detection switch that is turned in an ON state while unclamping and is turned in an OFF state at times other than while unclamping.

The clamp device 100 operates as follows.

When transitioning from unclamping to clamping in FIG. 3C, pressure oil is discharged from a release chamber on the front side (left side in FIG. 3C) of the outer piston, and pressure oil is supplied to a lock chamber on the rear side (right side in FIG. 3C) of the inner piston 113 c (FIG. 3C, an arrow P1). The clamp rod 103 has the mold M1 (or M2) clamped on the platen 4 a (or 4 b) by the hydraulic force in the lock chamber. On the other hand, the outer piston 110 has the collet 111 wedge-engaged with the pressure receiving surface 103 d to strongly press the clamp rod 103 to the guide hole 104.

When transitioning from clamping to unclamping, pressure oil in the lock chamber is discharged, and pressure oil is supplied to the release chamber (FIG. 3D, an arrow P2). Thus, the outer piston 110 is retreated to the upper right side along the guide hole 104 by the hydraulic force. According to this, first of all, the outer piston 110 presses the collet 111 to the upper right side to release the wedge engagement of the collet 111. Subsequently, the clamp rod 103 is retreated to the upper right side through a spring 116 on the rear side of the collet 111. Thereby, the mold M1 (or M2) related to the clamp rod 103 is released.

FIG. 4 shows a connection between the clamp device 100 and the control unit 9. The movable side platen 4 a and the fixed side platen 4 b are provided with four clamp devices 100, which are installed in respective T-slots 41, respectively. The clamp device 100 is supplied with compressed air from an air valve unit 15 and with pressure oil from a hydraulic unit 16. An electric signal from the clamp device 100 is connected to the control unit 9. This electric wiring connects the front limit switch 107, the rear limit switch 108, the lock LS 113 and the release LS 114. In the figure, the connection of only one clamp device 100 and the control unit 9 and the like is shown, but the other clamp devices 100 are similarly connected. The hydraulic unit 16 is provided with two systems of a lock side system for feeding pressure oil while clamping and a release side system for feeding pressure oil while unclamping, and a pressure switch is provided to each of them. A pressure switch for detecting the pressure of the lock side system is referred to as a lock pressure switch (a lock PS 17), and a pressure switch for detecting the pressure of the release side system is referred to as a release pressure switch (a release PS 18). Each pressure switch is turned in an ON state when the pressure is increased, and in an OFF state when the pressure is lowered. These switches are also state detection switches. Numeral reference 13 is a mold support block, and numeral references 14, 19 are electric connectors, respectively.

FIG. 5 shows a configuration of a remote diagnostic system. The control unit 9 attached to the injection molding machine 1 includes an arithmetic unit 9 a, a display unit 9 b, an input unit 9 c, a main body communication unit 9 d, and a main body memory 9 e. The control unit 9 is determined depending on the type of the clamp device attached to the injection molding machine 1, and stores the state of the main body from the power-on of the injection molding machine 1, the state of clamping, the ON/OFF state of each state detection switch when the state of state detection switch changes, and the time in the main body memory 9 e. The main body communication unit 9 d can read out the state of the main body, the state of clamping, the ON/OFF state of the state detection switch and the time from the main body memory 9 e through a short-range wireless communication (for example, a Bluetooth communication) and transmit to the outside. The control unit 9 includes lock buttons 22 a, 22 b for starting clamping operation to each of the clamp devices of the movable platen 4 a and the fixed platen 4 b, release buttons 23 a, 23 b and a reset button 24 for starting the unclamping operation to each of the movable platen 4 a and the fixed platen 4 b, and a mold replacement key 30 or the like which the operator switches operation to a molding machine operable mode and a mold replaceable mode.

A smartphone 12 possessed by the work manager includes an arithmetic unit 12 a, a display unit 12 b, an input unit 12 c, a portable communication unit (terminal communication unit) 12 d, and a portable communication part (terminal memory) 12 e, which is a portable telephone terminal capable of performing mail communication at a long distance through a network. The portable communication unit 12 d has a short-range wireless function. A remote diagnostic program 25 provided by the manufacturer for manufacturing the mold clamp system is downloaded to the portable (terminal) memory 12 e. With the remote diagnostic program 25, messages for defining states to be assumed are stored in each table for all combinations that can be taken by each state detection switch. Tables such as a P-table 26, a Q-table 27, an R-table 28, a Z-table 29, and an S-table 52 are stored. The P-table 26 stores messages for a T-slot automatic slide type clamp device having a mechanical lock mechanism. The Q-table 27, the R-table 28, the Z-table 29 and the S-table 52 stores messages for a T-slot manual type, a T-slot automatic slide type, a block fixed type clamp device and a magnet clamp 200, respectively.

Depending on whether or not the injection molding machine 1 is in the mold replacement mode, or depending on the clamp status by the control unit 9, even if the detection switches are the same, the states thereof have different meanings. The P-table 26, the Q-table 27, the R-table 28, and the Z-table 29 are prepared according to matching whether or not the injection molding machine 1 is in a mold replacement mode, and the combinations of the clamp statuses due to the control unit 9 with the ON/OFF combinations of these state detection switches. Whether or not the injection molding machine 1 is a mold replacement mode is hereinafter referred to as a “status of main body”. The “status of main body” can be defined according to a mold replacement key 30 that is switched by the operator. The clamp status is referred to as a “clamped state” of a process in which the clamp device 100 transits from unclamping to clamping, an “unclamped state” of a process in which the clamp device 100 transits from clamping to unclamping, or a state other than the foregoing.

For example, the state detection switch is described below, in case of a T-slot automatic slide type having a mechanical lock mechanism, the front limit switch 107, the rear limit switch 108, the release LS114, the lock LS113, the lock PS17 and the release PS18 are provided as the state detection switches for knowing the state of the clamp device 100, and the number of combinations of the ON/OFF states of the state detection switches is the largest in 16 ways. Thus, the amount of messages stored in the P-table 26 is largest.

On the other hand, since the block fixing type clamp device does not have an automatic slider function and its position does not change, it is not provided with the front limit switch 107 and the rear limit switch 108 and releases by an internal spring not pressure oil. Therefore, only the release LS114 and the lock LS113 are provided as a state detection switch. Thus, the number of the combinations of the ON/OFF states of the state detection switches is minimized in four ways. Thus, the amount of messages stored in the Z-table 29 is minimized.

The T-slot manual slide type having no mechanical lock mechanism has the front limit switch 107 and the lock PS17. Therefore, since there are two types of the state detection switches like the block fixed type, the Z-table 29 is applied. The automatic T-slot slide type has the front limit switch 107, the rear limit switch 108 and the lock PS17, and since there are three types of state detection switches, there are eight combinations, and the amount of messages stored in the R-table 28 is larger than that of the Z-table 29.

The clamp devices of the in-block manual slide type and the in-block automatic slide type have the state detection switches corresponding to the T-slot manual type clamp device and the T-slot automatic slide type clamp device, respectively. In this way, the clamp device varies depending on types, but at least two or more types of state detection switches are mounted.

The following table shows the contents of the P-table 26. The P-table 26 is applied to the clamp devices using the T-slot automatic slide type having the mechanical lock mechanism.

Table 1 shows the contents of messages stored in the P-table 26 in the power supply initial state of the injection molding machine 1. In the power supply initial state, the injection molding machine 1 is turned in a mold replacement mode.

In the following table, the lock LSPS is displayed as “ON” when both the lock LS113 and the lock PS17 are ON (AND condition), and as “OFF” when one of the lock LS113 and the lock PS17 is “OFF”. The release PSLS is also the same. The tables are common to the clamp devices of the movable platen 4 a and the fixed platen 4 b. Although neither lock PS17 nor release PS18 is a state detection switch mounted on the clamp device 100, information of the lock PS17 and the release PS18 is also taken into the table by setting the AND condition of the lock LS113 and the release LS114. Besides, any one of the lock LS113 and the lock PS17 may be omitted. In this case, “ON” or “OFF” is displayed based on the detection result of the other switch of the lock LS113 and the lock PS17.

TABLE 1 /* 0: power supply initial state-mold exchange mode */ Imput Front Limit Rear Limit Release Lock LS LS LSPS LSPS Smartphone screen display message Table Off Off Off Off (In operation) Pressure is reduced, No. 0 clamp position is unknown, and slider position is unknown. Table Off Off Off On (Abnormal) Pressure is incresed, and No. 1 slider is not at mold clamp position at lock position or forward limit switch is broken. Table Off Off On Off (In operation) Pressure is reduced, No. 2 release pressure is normal, and slider is operating at release position. Table Off Off On On (Sensor abnormal) Pressure is increased, No. 3 clamp position is abnormal, both lock and release are ON, and slider is operating. Table Off On Off Off (Abnormal) Pressure is reduced, clamp No. 4 position is unknown, and slider is at rearward position. Table Off On Off On (Sensor abnormal) Pressure is increased, No. 5 and slider is at rearward position at lock position. Table Off On On Off (Normal) Release pressure is normal, No. 6 releasing is completed when slider is at rearward position at release position. Table Off On On On (Sensor abnormal) Pressure is increased, No. 7 clamp position is abnormal, both lock and release are ON, and slider is at rearward position. Table On Off Off Off (Abnormal) Pressure is reduced, clamp No. 8 position is unknown, and slider is at mold clamp position. Table On Off Off On (Normal) Lock pressure is normal, and No. 9 locking is completed when slider is at mold clamp position. Table On Off On Off (In operation) Pressure is reduced, and No. 10 slider is at mold clamp position at release position. Table On Off On On (Sensor abnormal) Pressure is increased, No. 11 clamp position is abnormal, both lock and release are ON, and slider is at forward position. Table On On Off Off (Sensor abnormal) Pressure is reduced, No. 12 clamp position is unknown, slider position is abnormal, and both forward limit and rearward limit are ON. Table On On Off On (Sensor abnormal) Pressure is increased, No. 13 slider position is abnormal at lock position, and both forward limit and rearward limit are ON. Table On On On Off (Sensor abnormal) Pressure is reduced, No. 14 slider position is abnormal at release position, and both forward limit and rearward limit are ON. Table On On On On (Sensor abnormal) Pressure is reduced, No. 15 clamp position is abnormal, both lock and release are ON, slider position is abnormal, and forward limit and rearward are ON.

Table 2 also shows the contents of the messages of the P-table 26 in the power supply initial state of the control unit 9, and indicates that the injection molding machine 1 is in operation (in a state where injection molding is executable and not in a mold replacement mode). Since the power supply is in an initial state, the lock is in an uncompleted state.

TABLE 2 /* 0: power supply initial state-mold exchange mode */ Imput Front Limit Rear Limit Release Lock LS LS LSPS LSPS Smartphone screen display message Table Off Off Off Off (In operation) Pressure is reduced, No. 0 clamp position is unknown, and slider position is unknown. Table Off Off Off On (Abnormal) Pressure is incresed, and No. 1 slider is not at mold clamp position at lock position or forward limit switch is broken. Table Off Off On Off (In operation) Release pressure is No. 2 normal, and slider is operating at release position. Table Off Off On On (Sensor abnormal) Pressure is increased, No. 3 clamp position is abnormal, both lock and release are ON, and slider is operating. Table Off On Off Off (Abnormal) Pressure is reduced, clamp No. 4 position is unknown, and slider is at rearward position. Table Off On Off On (Sensor abnormal) Pressure is increased, No. 5 and slider is at rearward position at lock position. Table Off On On Off (Normal) Release pressure is normal, No. 6 releasing is completed when slider is at rearward position at release position. Table Off On On On (Sensor abnormal) Pressure is increased, No. 7 clamp position is abnormal, both lock and release are ON, and slider is at rearward position. Table On Off Off Off (Abnormal) Pressure is reduced, clamp No. 8 position is unknown, and slider is at mold clamp position. Table On Off Off On (Normal) Lock pressure is normal, and No. 9 locking is completed when slider is at mold clamp position. Table On Off On Off (In operation) Pressure is reduced, and No. 10 slider is at mold clamp position at release position. Table On Off On On (Sensor abnormal) Pressure is increased, No. 11 clamp position is abnormal, both lock and release are ON, and slider is at forward position. Table On On Off Off (Sensor abnormal) Pressure is reduced, No. 12 clamp position is unknown, slider position is abnormal, and both forward limit and rearward limit are ON. Table On On Off On (Sensor abnormal) Pressure is increased, No. 13 slider position is abnormal at lock position, and both forward limit and rearward limit are ON. Table On On On Off (Sensor abnormal) Pressure is reduced, No. 14 slider position is abnormal at release position, and both forward limit and rearward limit are ON. Table On On On On (Sensor abnormal) Pressure is reduced, No. 15 clamp position is abnormal, both lock and release are ON, slider position is abnormal, and forward limit and rearward are ON.

Table 3 shows the contents of the messages of the P-table 26 in the mold replacement mode of the control unit 9. In the mold clamp system, since the lock button 22 a (or 22 b) of the control unit 9 is pressed, the state of the clamp is a “clamped state”.

TABLE 3 /* 2: mold exchange mode, locking operation */ Imput Front Limit Rear Limit Release Lock LS LS LSPS LSPS Smartphone screen display message Table Off Off Off Off (In operation) Pressure is reduced, No. 0 clamp position is unknown, and slider position is unknown. Table Off Off Off On (Abnormal) Pressure is incresed, and No. 1 slider is not at mold clamp position at lock position or forward limit switch is broken. Table Off Off On Off (In operation) Release pressure is No. 2 normal, and slider is operating at release position. Table Off Off On On (Sensor abnormal) Pressure is increased, No. 3 clamp position is abnormal, both lock and release are ON, and slider is operating. Table Off On Off Off (Abnormal) Pressure is reduced, clamp No. 4 position is unknown, and slider is at rearward position. Table Off On Off On (Sensor abnormal) Pressure is increased, No. 5 and slider is at rearward position at lock position. Table Off On On Off (Normal) Release pressure is normal, No. 6 releasing is completed when slider is at rearward position at release position. Table Off On On On (Sensor abnormal) Pressure is increased, No. 7 clamp position is abnormal, both lock and release are ON, and slider is at rearward position. Table On Off Off Off (Abnormal) Pressure is reduced, clamp No. 8 position is unknown, and slider is at mold clamp position. Table On Off Off On (Normal) Lock pressure is normal, and No. 9 locking is completed when slider is at mold clamp position. Table On Off On Off (In operation) Pressure is reduced, No. 10 and slider is at mold clamp position at release position. Table On Off On On (Sensor abnormal) Pressure is increased, No. 11 clamp position is abnormal, both lock and release are ON, and slider is at forward position. Table On On Off Off (Sensor abnormal) Pressure is reduced, No. 12 clamp position is unknown, slider position is abnormal, and both forward limit and rearward limit are ON. Table On On Off On (Sensor abnormal) Pressure is increased, No. 13 slider position is abnormal at lock position, and both forward limit and rearward limit are ON. Table On On On Off (Sensor abnormal) Pressure is reduced, No. 14 slider position is abnormal at release position, and both forward limit and rearward limit are ON. Table On On On On (Sensor abnormal) Pressure is reduced, No. 15 clamp position is abnormal, both lock and release are ON, slider position is abnormal, and forward limit and rearward are ON.

Table 4 shows the contents of the messages of the P-table 26 in the mold replacement mode by the control unit 9. In the mold clamp system, since the release button 23 a (or 23 b) of the control unit 9 is pressed, the state of the clamp is “unclamped state”.

TABLE 4 /* 3: mold exchange mode, releasing operation */ Imput Front Limit Rear Limit Release Lock LS LS LSPS LSPS Smartphone screen display message Table Off Off Off Off (In operation) Pressure is reduced, No. 0 clamp position is unknown, and slider position is unknown. Table Off Off Off On (Abnormal) Pressure is incresed, and No. 1 slider is not at mold clamp position at lock position or forward limit switch is broken. Table Off Off On Off (In operation) Release pressure is No. 2 normal, and slider is operating at release position. Table Off Off On On (Sensor abnormal) Pressure is increased, No. 3 clamp position is abnormal, both lock and release are ON, and slider is operating. Table Off On Off Off (Abnormal) Pressure is reduced, clamp No. 4 position is unknown, and slider is at rearward position. Table Off On Off On (Sensor abnormal) Pressure is increased, No. 5 and slider is at rearward position at lock position. Table Off On On Off (Normal) Release pressure is normal, No. 6 releasing is completed when slider is at rearward position at release position. Table Off On On On (Sensor abnormal) Pressure is increased, No. 7 clamp position is abnormal, both lock and release are ON, and slider is at rearward position. Table On Off Off Off (Abnormal) Pressure is reduced, clamp No. 8 position is unknown, and slider is at mold clamp position. Table On Off Off On (Normal) Lock pressure is normal, and No. 9 locking is completed when slider is at mold clamp position. Table On Off On Off (In operation) Pressure is reduced, No. 10 and slider is at mold clamp position at release position. Table On Off On On (Sensor abnormal) Pressure is increased, No. 11 clamp position is abnormal, both lock and release are ON, and slider is at forward position. Table On On Off Off (Sensor abnormal) Pressure is reduced, No. 12 clamp position is unknown, slider position is abnormal, and both forward limit and rearward limit are ON. Table On On Off On (Sensor abnormal) Pressure is increased, No. 13 slider position is abnormal at lock position, and both forward limit and rearward limit are ON. Table On On On Off (Sensor abnormal) Pressure is reduced, No. 14 slider position is abnormal at release position, and both forward limit and rearward limit are ON. Table On On On On (Sensor abnormal) Pressure is reduced, No. 15 clamp position is abnormal, both lock and release are ON, slider position is abnormal, and forward limit and rearward are ON.

Table 5 shows the contents of the messages of the P-table 26 in an operation mode (a molding machine operation mode) of the control unit.

TABLE 5 /* 4 in operation */ Input Front Limit Rear Limit Release Lock LS LS LSPS LSPS Smartphone screen display message Table Off Off Off Off (Abnormal) Pressure is reduced, clamp No. 0 position is unknown, and slider position is unknown. Table Off Off Off On (Abnormal) Pressure is incresed, and No. 1 slider is not at mold clamp position at lock position or forward limit switch is broken. Table Off Off On Off (Abnormal) Pressure is reduced, and No. 2 release position and slider position are unknown. Table Off Off On On (Sensor abnormal) Pressure is increased, No. 3 clamp position is abnormal, both lock and release are ON, and slider is operating. Table Off On Off Off (Abnormal) Pressure is reduced, clamp No. 4 position is unknown, and slider is at rearward position. Table Off On Off On (Sensor abnormal) Pressure is increased, No. 5 and slider is at rearward position at lock position. Table Off On On Off (Abnormal) Pressure is reduced, and No. 6 release position and slider position are abnormal (at rearward position). Table Off On On On (Sensor abnormal) Pressure is increased, No. 7 clamp position is abnormal, both lock and release are ON, and slider is at rearward position. Table On Off Off Off (Abnormal) Pressure is reduced, clamp No. 8 position is unknown, and slider is at mold clamp position. Table On Off Off On (Normal) Lock pressure is normal, and No. 9 locking is completed when slider is at mold clamp position. Table On Off On Off (Abnormal) Pressure is reduced, and No. 10 slider is at mold clamp position at release position. Table On Off On On (Sensor abnormal) Pressure is increased, No. 11 clamp position is abnormal, both lock and release are ON, and slider is at forward position. Table On On Off Off (Sensor abnormal) Pressure is reduced, No. 12 clamp position is unknown, slider position is abnormal, and both forward limit and rearward limit are ON. Table On On Off On (Sensor abnormal) Pressure is increased, No. 13 slider position is abnormal at lock position, and both forward limit and rearward limit are ON. Table On On On Off (Sensor abnormal) Pressure is reduced, No. 14 slider position is abnormal at release position, and both forward limit and rearward limit are ON. Table On On On On (Sensor abnormal) Pressure is reduced, No. 15 clamp position is abnormal, both lock and release are ON, slider position is abnormal, and forward limit and rearward are ON.

Since the number of state detection switches of the clamp device 100 is four, there is 16 combinations of states of the switches. For each of them, the manufacturer of the mold clamp system anticipates all the combinations in a recursive method in advance, and defines the diagnostic states of the clamp device for the P-table 26 as the contents of the message without no omissions. The contents of the message are comparable to the contents of the diagnostic know-how of the manufacturer of the mold clamp system. The contents of the message are similarly determined for the Q-table 27, the R-table 28, and the Z-table 29.

FIGS. 6A to 6D show an operation of the remote diagnostic program 25 downloaded to the smartphone 12. The remote diagnostic program 25 communicates with the main body side communication unit 9 d of the control unit 9 to read the status of the main body, the clamp status, the ON/OFF state of each status detection switch, and the time from the main body side memory 9 e through a short-distance wireless communication. When the remote diagnostic program 25 is started by the icon 33 in FIG. 6A, a list of devices that can perform short-range wireless communication is displayed. In a manufacturing site F (FIG. 1A), a plurality of injection molding machines 1 are present, and identification information 34 a to 34 d that the injection molding machines respectively have are displayed (FIG. 6B). The identification information 34 a to 34 c is for a control unit of the clamp device using hydraulic pressure, and the identification information 34 d is for a control unit for controlling the magnet clamp. In these identification information, what type of clamp device is connected is specified, thereby having the remote diagnostic program 25 know what type of clamp device is connected.

When the operator selects one piece of identification information, a screen shown in FIG. 6C is displayed. On window screens of a positioning pin 35, a clamp operation 36, and a clamp position 37, phrases such as “pin extracting”, “lock completed”, “release completed”, “advancing”, “retreating”, and “clamp abnormality” are shown, and are highlighted for the corresponding operations. A “login” button 38 is to read the status of the main body, the clamp status, the ON/OFF status of each status detection switch, and the time from the main body side memory 9 e as history for the period from power-on of the injection molding machine 1 to the present. When the “login” button 38 is selected, histories shown in FIG. 6D are imported to the smartphone 12.

The smartphone 12 selects one of the P-table 26, the Q-table 27, the R-table 28, and the Z-table 29 according to the status of the main body and the clamp status, and reads out and displays a message corresponding to the ON/OFF state of the state detection switch. In this example, since the control unit 9 selected by the smartphone 12 based on the identification information controls the clamp device of the T-slot manual slide having the mechanical lock mechanism, the remote diagnostic program 25 selects the P-table 26 on the portable memory 12 e. Then, since the injection molding machine 1 is in the mold exchanging mode and the lock button 22 a (or 22 b) is pressed to make a transition from unclamping to clamping, Table 3 of the P-table is selected. The messages TX9 and TX10 correspond to messages in the third row of Table 3, the message TX11 is a message in the tenth row thereof, and the message TX12 is a message in the second row thereof. These indicate an abnormality that the housing 102 of the clamp device is not at a proper position for clamping even though only the lock LSPS is in the ON state. Besides, the messages TX1 to TX8 indicate the process of the operation of the clamp device in chronological order, and the explanation thereof will be omitted.

As described above, according to the present embodiment, by anticipating all combinations in advance by a recursive method for the combinations of all outputs of the forward limit switch 107, the rearward limit switch 108, the lock LS 113, the release LS 114, the lock PS 17, and the release PS 18, the state of the main body of the injection molding machine, and the clamp status, and by defining the diagnostic states of the clamp device to those combinations as the contents of message without omissions, unexpected conditions are eliminated and message contents that can build a highly reliable system can be provided. The work manager refers to the message contents, thereby enabling the correspondence on the working site to quickly correspond.

When the work manager selects a message transmission button 39, the status of the main body, the clamp status, and the information of the state detection switch transmitted from the control unit 9 to the smartphone 12 are sent to the maintenance department 32 of the mold clamp system manufacturer through the network 31 by e-mail. The maintenance department that has received the e-mail can examine and prepare for a countermeasure in advance before arriving at the manufacturing site.

Next, an example in which a magnet clamp 200 is mounted as a mechanism of the clamp devices 6 a, 6 b will be described with reference to FIGS. 7A to 7E. FIG. 7A is a front view of the magnet clamp 200 as the clamp device 6 a at a movable platen side, and FIG. 7B is a front view of the magnet clamp 200 as the clamp device 6 b at a fixed platen side. The magnet clamp 200 as the clamp device 6 a at the movable platen side has a through hole 201 through which the ejector rod 10 passes, but the magnet clamp 200 as the clamp device 6 b at the fixed platen side does not have the through hole 201. The clamp devices 6 a, 6 b have substantially the same configuration except that the arrangement patterns of magnet blocks 202 are different. A large number of magnet blocks 202 are arranged on the surface of the magnet clamp 200. Each magnet block 202 has magnets that polarity cannot be reversed and magnets that polarity can be reversed (these magnets include alnico magnets, iron/chromium/cobalt magnets, and other magnets. Hereinafter, the alnico magnets will be described as an example), and can be switched between a magnetic circuit that closes (demagnetizes) in the plate and a magnetic circuit that passes through the mold (magnetizes) by controlling the magnetic polarity of the alnico magnet with a coil. Proximity sensors 203, 204 for detecting the proximity state of the mold on the surface of the magnet clamp 200 are provided on the clamp devices 6 a, 6 b, respectively.

FIG. 7C shows an electric circuit of the magnet block 202 on one side of the clamp devices 6 a, 6 b. A magnetizing coil 43 for reversing the magnetic polarity of an alnico magnet (not shown), a sensor coil 44 for measuring an attractive force, and a current sensor 45 for measuring a current value of the magnetizing coil 43 are arranged on each magnet block 202. Here, the sensor coil 44 is wound around a magnetic circuit passing through the alnico magnet to detect a change of the magnetic flux. The sensor coils 44 of the magnet blocks 202 are serially connected, and each of the clamp devices 6 a, 6 b can perform one detection. The magnet clamp 200 is divided into a plurality of regions in advance, in which temperature sensors 46 for measuring the temperature of the regions are provided respectively.

FIG. 7D shows a power supply for driving the magnetizing coil 43 of the whole magnet block 202 on one side of the clamp device 6 a or the clamp device 6 b. The power supply full-wave rectifies an external AC power supply 49 with a thyristor 47. A current detector 48 measures the current flowing through the thyristor 47 based on terminal voltage of the resistor.

In summary, the detectors provided on the magnet clamp 200 as the clamp device 6 a or the clamp device 6 b are firstly the proximity sensors 203, 204 and a current detector 48 for measuring the whole current, and further, a large number of temperature sensors 46 respectively provided for areas of the magnet clamp 200, current sensors 45 and sensor coils 44 respectively provided for the magnet blocks 202. The magnet clamp 200 also includes detectors that can detect not only binary values of on and off but also intermediate values, which are different from the state detection switches of the clamp devices 6 a, 6 b of T-slot manual type, T-slot automatic slide type, manual slide type in block, automatic slide type in block, block fixed type, and type having mechanical lock mechanism.

Returning to FIG. 5 , the control unit 9 stores an upper limit value of the detection current of the current detector 48, an upper limit value and a lower limit value of the current of each current sensor 45, a set temperature and a specified temperature of the temperature sensor 46, and a set value of the induction current of the sensor coil 44 (hereinafter, collectively referred to as “reference values”) in the main body side memory 9 e. Here, the upper limit value for the detection current of the current detector 48 is, for example, 5 amperes, and is used as a criterion for determining whether a short circuit has occurred due to insulation deterioration or damage to the thyristor 47. The upper limit value and the lower limit value for each current sensor 45 are, for example, 30% or more of a design value or 30% or less thereof, and are used as a criterion for determining deterioration of the magnetized coil 43. In magnetically attracting and fixing the mold to the fixed platen and the movable platen, when the induction current flowing through a sensor coil which is a coil similar to the sensor coil 44 but different from the sensor coil falls below 75% of the reference value, it is determined that the mold is abnormal. The set temperature and the specified temperature of the temperature sensor 46 are, for example, 110° C. for the set temperature and 122° C. for the specified temperature. The specified temperature is a temperature which a magnetic holding force of the magnet is easily lost, and the set temperature is a temperature which warns that the temperature is approaching the specified temperature. The set value for the sensor coil 44 is made, for example, 25% loss of magnetic force. When the magnetic force is lost, the magnetic flux fluctuates, and the sensor coil 44 detects the electromotive force generated by the magnetic flux fluctuation. The voltage and the fluctuation time are integrated to be converted to a lost magnetic flux.

The control unit 9 generates a three-digit error code based on the reference value and stores it in the main unit side memory 9 e. The error codes are shown in the table below in the column marked as Indication.

TABLE 6 Clasification Indication Content Cause and Solution Load U S Current value during Turn on the power again. fixed side operation There is insulation exceeds the upper limit. deterioration/deterioration/ M Current value during short circuit of the coil in movable side operation the plate, and abnormality exceeds the upper limi. between the control panel L S Current value during and the plate wiring. fixed side operation Or, the power supply voltage exceeds the lower limit. may fluctuate. M Current value during Check the power supply movable side operation voltage. exceeds the lower limi.t E 1 Drive circuit leak current is generated inside the control panel. Mold F S The fixed mold abnormal Release the mold on the detection section is error side. below the set value. Check that there is no gap M The morvable mold or rust on the back side abnormal detection section of the mold near the mold is below the set value. abnormality detection section. Temperature t 0 Fixed side temperature Plate temperature is rising. is approaching the Reduce the temperature of upper limit of the the plate. specified temperature of the plate. Movable side temperature is approaching the upper limit of the specified temperature of the plate. 1 Fixed side temperature exceeds the upper limit of the specified temperature of the plate. Movable side temperature exceeds the upper limit of the specified temperature of the plate. Sensor E 4 1 Fixed side proximity Release the mold on the detection has been target side and restore turned OFF. the presence. 2 Movable side proximity Check that there is no gap detection has been or rust on the back side turned OFF. of the mold near the proximity detection. 3 Fixed side proximity Detection of mold peeling. detection has been Check that it is within the turned OFF once and specification range. turned ON again. Or, check if there is any 4 Movable side proximity abnormality in the wiring. detection has been turned OFF once and turned ON again. Attractive E 5 1 Fixed side magnetizing Check that it is not force force is smaller than smaller than the default the default magnetizing magnetizing force (25% of force. the plate clamping capacity). 2 Movable side magnetizing Or, check if there is any force is smaller than the abnormality in the default magnetizing force. attractive force detection coil or wiring.

Explaining the error code, the third digit indicates classifications. Various codes of classifications U, L, F, t, and E are defined. The classifications U and L are codes indicating a load abnormality, the former indicating an error exceeding the upper limit value, and the latter indicating an error below the lower limit value. The classification F is a code indicating a mold abnormality. The classification t is a code indicating a temperature abnormality. The classification E is a code indicating an abnormal attractive force.

The second and first digits indicate the location of each error.

In the classification U, the second digit indicates whether the current sensor 45 that has detected the error exists on the fixed platen 4 b or the movable platen 4 a, or is the current detector 48. The first digit is a unique number assigned to the current sensor 45. The “S” in the second digit indicates that the current sensor 45 is on the fixed platen 4 b side. The second digit “M” indicates that the current sensor 45 is on the movable platen 4 a side. The second digit “E” indicates that the current detector 48 is used. Since there is one current detector 48 in the magnet clamp 200, the first digit is “1”.

In the classification F, when the current sensor 45 detects a current value of 75% or less indicating a mold abnormality, the second digit indicates the type of the fixed platen 4 b or the movable platen 4 a, and the first digit indicates the number of the current sensor 45 in which an error has occurred.

In the classification t, “0” in the second digit indicates that the temperature has exceeded the set temperature, and “1” indicates that the temperature has exceeded the specified temperature. The first digit indicates the number of the temperature sensor 46 where the error has occurred. Besides, the number of the temperature sensor 46 is a number that can be specified by the first digit even if the number of the fixed platens 4 b and the number of the movable platens 4 a are added.

The classification E indicates the sensor abnormality or another abnormality of the attractive force abnormality. The second digit indicates the type of abnormality, where “4” is a sensor abnormality and “5” is an attractive force abnormality. In the sensor abnormality “4”, the first digit indicates the detection state of the proximity sensors 203, 204 including a temporal element. In the attractive force abnormality “5”, the first digit indicates which of the sensor coils 44 of the fixed platen 4 b and the movable platen 4 a has detected the abnormality.

In FIG. 5 , the remote diagnostic program 25 downloaded to the portable memory 12 e stores messages about “contents” and “cause and countermeasure” for the error code in an MG table 42. The specific contents of “contents” and “cause and countermeasure” are as shown in Table 6.

In FIG. 7E, the smartphone 12 reads out and displays a message corresponding to the error code from the MG table. In this example, since the control unit 9 selected by the smartphone 12 based on identification information controls the magnet clamp, the remote diagnostic program 25 selects the MG table 42.

FIG. 7E shows contents displayed on the smartphone 12. The display unit 9 b indicates the “contents” and “cause and countermeasures” selected from Table 6 based on the three-digit error code 50 on a window 51 together with the error code.

When the remote diagnostic system diagnoses that the magnet clamp is abnormal, the remote diagnostic system can indicate possible causes similarly to the above-described clamp devices other than the magnet clamp, and then further provide an operator with next possible operations. The smartphone 12 holds and displays magnet clamp abnormal messages (S tables described later) for the initial power state of the injection molding machine 1, the operation of the injection molding machine 1 (in a state where the injection molding can be performed, not in the mold replacement mode), the mold replacement mode and the (molding machine) operation mode. In this case, in the other clamp devices described above, it is possible to determine whether the mold is locked or released according to the ON/OFF state of each state detection switch. On the other hand, since the magnet clamp 200 does not have a state detection switch corresponding to the state detection switch of the clamp device, it is necessary to separately create information corresponding to this.

FIG. 8 and FIG. 9 show two processing programs (a lock completion state detection unit 60 and a release completion state detection unit 70) for detecting whether the mold is locked (hereinafter, referred to as “lock completed”) or released (hereinafter, referred to as “release completed”). These are executed by the control unit 9. FIG. 8 shows a flow of the lock completion state detection unit. The lock completion state detection unit 60 detects ON/OFF of “lock completed”. Besides, the ON/OFF of “lock completed” is a binary representation of the processing result, such as the output from the state detection switch. A lock display flag F1 and a release display flag F2 (see FIG. 5 ) are provided in the main body side memory 9 e.

The control unit 9 stores, similarly to the clamp devices other than the magnet clamp described above, the state of the main body after the power of the injection molding machine 1, whether the magnet clamp is in the clamped state or the unclamped state, each normal/abnormal state (ON/OFF state) when the state of “lock completed” or “release completed” changes, information indicating the proximity/separation of the proximity sensors 203, 204 as ON/OFF, and the time in the main body side memory 9 e.

When the lock button 22 a (or 22 b) is pressed, a lock command is issued, and the control unit 9 drives the magnetizing coil 43 of the magnet clamp 200 to put the magnet clamp 200 in a magnetized state. On the other hand, when the control unit 9 receives the lock command (step 61), the control unit 9 lowers (deletes) the “release ON display flag F2” of the main body side memory 9 e to delete the previous state (step 62). Next, the load state, the mold state, and the attractive force are checked. These are performed based on error codes generated by the control unit 9.

As described above, the load states (classification U, classification L) are determined based on the detection result of the current sensor 45 and the current detector 48, and the mold state (classification F) is determined by the detection result of the current sensor 45, and the attractive force (classification E) is determined based on the detection result of the sensor coil 44.

It is detected whether an abnormal error code has been generated in the “Load” item of the error code classification (step 63). If an abnormal error code has been generated, the “Lock display flag F1” is set to “OFF” as lock not completed (step 67). Next, it is detected whether an abnormal error code has been generated in the “Mold” item of the error code classification (step 64). If an abnormal error code has been generated, the “Lock display flag F1” is set to “OFF” as lock not completed (step 67). Then, it is detected whether an abnormal error code has been generated in the “Attractive force” item in the error code classification (step 65). If an abnormal error code has been generated, the “Lock display flag F1” is set to “OFF” as lock not completed (step 67). Otherwise, the “Lock display flag F1” is set to “ON” as lock completed (step 66).

FIG. 9 shows a flow of a release completion state detection unit 70. The release completed state detection unit detects ON/OFF of “Release completed”. When the release button 23 a (or 23 b) is pressed, a release command is issued, and the control unit 9 drives the magnetizing coil 43 of the magnet clamp 200 to put the magnet clamp 200 in a demagnetized state. On the other hand, when receiving the release command (step 71), the control unit 9 resets (erases) the “Lock display flag F1” of the main body side memory 9 e to erase the previous state (step 72). Next, the load state is confirmed. This is also performed based on the error code generated by the control unit 9. It is detected whether an abnormal error code has been generated in the “Load” item of the error code classification (step 73). If an abnormal error code has been generated, the “Release display flag F2” is set to “OFF” as release not completed (step 76). Next, it is detected whether an abnormal error code has been generated in the “Mold” item of the error code classification (step 74). If an abnormal error code has been generated, the “Release display flag F2” is set to “OFF” as release not completed (step 76). Otherwise, the “Release display flag F2” is set to “ON” as release completed (step 75).

Messages are stored for each state that can be combined by the ON/OFF state due to the three state detectors of the “Lock display flag F1”, the “Release display flag F2” and a proximity sensor 203 (or 204). The proximity sensor 203 (or 204) is provided on the surface of the magnet clamp and outputs a mold detection signal (ON) when the distance from the sensor to the mold is within a predetermined range. Otherwise, it is OFF.

The following table shows contents of the S-table 52. The S-table 52 is applied to the magnet clamp 200. In the case of the magnet clamp 200, there are three ON/OFF states detected respectively by the lock completion state detection unit 60, the release completion state detection unit 70 and the proximity sensor 203 (or 204). Therefore, there are eight combinations of states.

Table 7 shows contents of the messages stored in the S-table 52 in the initial state of the power supply of the injection molding machine 1. In the initial state of the power supply, the injection molding machine 1 is in a mold replacement mode.

TABLE 7 0: Power supply initial state, Mold replacement mode Proximity Release Lock Screen Normal/ sensor completed completed display message Abnormal Cause and Solution Table No. 0 Off Off Off Clamp state is undefined. Normal — Table No. 1 Off Off On Locked, status is OFF. Normal — Table No. 2 Off On Off Release completed. Normal — Table No. 3 Off On On Clamp state is abnormal. Abnormal Clamp state is abnormal. Perform the release operation to make it normal. Table No. 4 On Off Off Clamp state is undefined. Normal — Table No. 5 On Off On Locked, status is ON. Normal — Table No. 6 On On Off Released, status is ON. Normal — Table No. 7 On On On Clamp state is abnormal. Abnormal Clamp state is abnormal. Perform the release operation to make it normal.

Table 8 also shows contents of the message in the S-table 52 in the initial state of the power supply of the control unit 9, but wherein the injection molding machine 1 is in operation (injection molding is executable, and not in the mold replacement mode). Since the power supply is in the initial state, the lock is not the completed state.

TABLE 8 1: Power supply initial state, Operating (Table to be referred when mold replacement is OFF in the lock incomplete state) Proximity Release Lock Normal/ sensor completed completed Screen display message Abnormal Cause and Solution Table No. 0 Off Off Off Clamp state is undefined. Abnormal Clamp state is undefined. Perform the lock operation to make it normal. Table No. 1 Off Off On Locked, status is OFF. Abnormal Release the mold target side and restore the status. Check that there is no gap or rust on the back side of the mold near the proximity detection. Detection of mold peeling. Check that it is within the specification range. Or, check for any abnormalities in the wiring. Table No. 2 Off On Off Release completed. Abnormal Released during “Mold replacement OFF”. Perform the lock operation to make it normal. Table No. 3 Off On On Clamp state is abnormal. Abnormal Clamp state is abnormal. After performing the release operation, perform the lock operation to return to the normal state. Table No. 4 On Off Off Clamp state is undefined. Abnormal Clamp state is undefined. Perform the lock operation to make it normal. Table No. 5 On Off On Locked, status is ON. Normal — Table No. 6 On On Off Released, status is ON. Abnormal Released during “Mold replacement OFF”. Perform the lock operation to make it normal. Table No. 7 On On On Clamp state is abnormal. Abnormal Clamp state is abnormal. After performing the release operation, perform the lock operation to return to the normal state.

Table 9 shows contents of the messages in the S-table 52 in the mold replacement mode of the control unit 9. In the mold clamp system, since the lock button 22 a (or 22 b) of the control unit 9 is pressed, the clamp state is the “clamp state”.

TABLE 9 2: Mold replacement mode, Lock operation Proximity Release Lock Normal/ sensor completed completed Screen display message Abnormal Cause and Solution Table No. 0 Off Off Off Locked Normal — Table No. 1 Off Off On Locked, status is OFF. Normal — Table No. 2 Off On Off Release completed. Normal — Table No. 3 Off On On Clamp state is abnormal. Abnormal Clamp state is abnormal. Perform the release operation to make it normal. Table No. 4 On Off Off Locked Normal — Table No. 5 On Off On Locked, status is ON. Normal — Table No. 6 On On Off Released, status is ON. Normal — Table No. 7 On On On Clamp state is abnormal. Abnormal Clamp state is abnormal. Perform the release operation to make it normal.

Table 10 shows contents of the messages in the S-table 26 when the control unit is in the mold replacement mode. In the mold clamp system, the release button 23 a (or 23 b) of the control unit 9 is pressed, so that the clamp state is the “unclamped state”.

TABLE 10 2: Mold replacement mode, Lock operation Proximity Release Lock Normal/ sensor completed completed Screen display message Abnormal Cause and Solution Table No. 0 Off Off Off Locked Normal — Table No. 1 Off Off On Locked, status is OFF. Normal — Table No. 2 Off On Off Release completed. Normal — Table No. 3 Off On On Clamp state is abnormal. Abnormal Clamp state is abnormal. Perform the release operation to make it normal. Table No. 4 On Off Off Locked Normal — Table No. 5 On Off On Locked, status is ON. Normal — Table No. 6 On On Off Released, status is ON. Normal — Table No. 7 On On On Clamp state is abnormal. Abnormal Clamp state is abnormal. Perform the release operation to make it normal.

Table 11 shows contents of the messages in the S-table 52 when the control unit is in the (molding machine) operation mode.

TABLE 11 4: Ongoing (operating) Proximity Release Lock Normal/ sensor completed completed Screen display message Abnormal Cause and Solution Table No. 0 Off Off Off Clamp state is undefined. Abnormal Clamp state is undefined. Perform the lock operation to make it normal. Table No. 1 Off Off On Locked, status is OFF. Abnormal Release the mold target side and restore the status. Check that there is no gap or rust on the back side of the mold near the proximity detection. Detection of mold peeling. Check that it is within the specification range. Or, check for any abnormalities in the wiring. Table No. 2 Off On Off Release completed. Abnormal Released during “Mold replacement OFF”. Perform the lock operation to make it normal. Table No. 3 Off On On Clamp state is abnormal. Abnormal Clamp state is abnormal. After performing the release operation, perform the lock operation to return to the normal state. Table No. 4 On Off Off Clamp state is undefined. Abnormal Clamp state is undefined. Perform the lock operation to make it normal. Table No. 5 On Off On Locked, status is ON. Normal — Table No. 6 On On Off Released, status is ON. Abnormal Released during “Mold replacement OFF”. Perform the lock operation to make it normal. Table No. 7 On On On Clamp state is abnormal. Abnormal Clamp state is abnormal. After performing the release operation, perform the lock operation to return to the normal state.

Returning to FIG. 6A, when the operator starts the remote diagnostic program 25 with the icon 33, a list of devices that can perform short-range wireless communication is displayed. When the operator selects the identification information 34 d of the control unit for controlling the magnet clamp, the screen shown in FIG. 6C is displayed like other clamp devices. When the “login” button 38 is selected, history shown in FIG. 6D is collected on the smartphone 12. In this example, since the magnet clamp is controlled, the S-table 52 is selected. Then, one of Tables 7 to 11 is selected according to the mode of the injection molding machine 1, and corresponding messages are displayed on the display unit 12 b.

In the above embodiment, the remote diagnostic program 25 is installed in the smartphone 12, which is possessed by the work manager H, to wirelessly read out the history of ON/OFF states of the state detection switch for the status of the main body and the clamp status from the main body side memory and display the diagnosis result. On the other hand, reading may be performed with a wired terminal device instead of a wireless terminal device such as the smartphone 12. For example, a terminal device having an arithmetic unit, a display unit, an input unit, a wired communication unit, and a memory is prepared, and the wired communication unit is provided in the control unit 9. A remote diagnostic program is set in the terminal device, the program is started, and the ON/OFF states of the state detection switch for the status of the main body and the clamp status from the main body side memory 9 e may be read out through the wired communication unit of the control unit 9, and messages corresponding to the read history may be collected from the terminal side memory to be displayed on the display unit. In this case, for example, an existing connection method such as an RS-232 C connection or a USB connection can be used for the wired communication with the control unit 9.

DESCRIPTION OF SYMBOLS

-   -   1 injection molding machine     -   2 movable crane     -   3 belt conveyor     -   4 a platen, movable platen     -   4 b platen, fixed platen     -   5 guide rod     -   6 a, 6 b clamp device     -   7 controller     -   9 control unit     -   9 a arithmetic unit     -   9 b display unit     -   9 c input unit     -   9 d main body side communication unit     -   9 e main body side memory     -   10 ejector rod     -   12 smartphone     -   12 a arithmetic unit     -   12 b display unit     -   12 c input unit     -   12 d portable side communication unit     -   12 e portable side memory     -   13 mold support block     -   15 air valve unit     -   16 hydraulic unit     -   22 a, 22 b lock button     -   23 a, 23 b release button     -   24 reset button     -   25 remote diagnostic program     -   26 P-table     -   27 Q-table     -   28 R-table     -   29 Z-table     -   30 mold replacement key     -   33 icon     -   34 a to 34 d identified information     -   36 clamp operation     -   37 clamp position     -   38 button     -   39 message transmission button     -   41 T-slot     -   42 MG table     -   43 magnetizing coil     -   44 sensor coil     -   45 current sensor     -   46 temperature sensor     -   47 thyristor     -   48 current detector     -   49 AC power supply     -   50 error code     -   51 window     -   52 S-table     -   60 lock completion state detection unit     -   70 release completion state detection unit     -   100 clamp device     -   101 T-leg     -   102 housing     -   103 clamp rod     -   103 a clamping member     -   103 b flange     -   103 c inner piston     -   103 d pressure receiving surface     -   104 guide hole     -   104 a small-diameter portion (hole)     -   104 b large-diameter portion (hole)     -   105 base     -   106 pneumatic cylinder     -   107 forward limit switch     -   108 rearward limit switch     -   109 output member     -   110 outer piston     -   111 collet     -   112 a, 112 b hook part     -   115 operating member     -   116 spring     -   200 magnet clamp     -   201 through hole     -   202 magnet block     -   203, 204 proximity sensor 

1. (canceled)
 2. (canceled)
 3. A remote diagnostic system of a mold handling device loaded with a magnet platen mounting including a magnet clamp mounted on a platen, said magnet platen mounting including a proximity sensor for detecting a proximity/separation state with a mold provided on a surface of the magnet clamp; a current sensor for detecting current of each magnetizing coil operably connected to each of a plurality of magnet blocks of the magnet clamp; a sensor coil for detecting an attractive force; and a current detector for measuring current for driving the plurality of magnet blocks, wherein said remote diagnostic system, comprising: a control unit having a main body side memory for determining normal/abnormal state at a time with respect to each of locking instruction and releasing instruction whether release completion and lock completion are normal or abnormal based on detection values detected by the sensor coil and the current detector, and storing together with information as to a status of a main body of the mold handling device of whether or not the main body of the mold handling device is in a mold replacement mode, information as to whether the magnet clamp is in a clamped state or an unclamped state or other state, and time information; and a terminal device comprising: a terminal side memory, said terminal side memory being configured, as to each case of the status of the main body of the mold handling device and the information as to whether the magnet clamp is in the clamped state or the unclamped state or other state, to store messages for diagnosing failures for all combinations of the normal/abnormal state and the proximity/separation state of the proximity sensor; a terminal side communication unit for reading the status of the main body of the mold handling device and the normal/abnormal state and histories of the proximity/separation state by a wireless communication or a wired communication; and a display unit for obtaining and displaying messages corresponding to the read histories from the terminal side memory. 